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Universidade de Aveiro
Ano 2014
Departamento de Biologia
Bruno Ricardo da Silva Correia
Evaluation of the genotoxicity effect and antioxidant response of two nanoparticles in Eisenia andrei
Avaliação dos efeitos genotóxicos e resposta antioxidante de duas nanoparticulas em Eisenia andrei
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DECLARAÇÃO Declaro que este relatório é integralmente da minha autoria, estando devidamente referenciadas as fontes e obras consultadas, bem como identificadas de modo claro as citações dessas obras. Não contém, por isso, qualquer tipo de plágio quer de textos publicados, qualquer que seja o meio dessa publicação, incluindo meios eletrónicos, quer de trabalhos académicos.
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Universidade de Aveiro
Ano 2014
Departamento de Biologia
Bruno Ricardo da Silva Correia
Evaluation of the genotoxicity effect and antioxidant response of two nanoparticles in Eisenia andrei
Avaliação dos efeitos genotóxicos e resposta antioxidante de duas nanoparticulas em Eisenia andrei
Dissertação apresentada à Universidade de Aveiro para cumprimento dos requisitos necessários à obtenção do grau de Mestre em Biologia Molecular e Celular, realizada sob a orientação científica da Doutora Ruth Maria de Oliveira Pereira, Professora Auxiliar Convidada do Departamento de Biologia da Universidade do Porto, e coorientação da Doutora Sónia Alexandra Leite Velho Mendo Barroso, Professora Auxiliar c/Agregação do Departamento de Biologia da Universidade de Aveiro.
This research is part of the project REALISE (PTDC/AAC-AMB/120697/2010) funded by the Portuguese Government (Program Ciência - Inovação 2010) and by the European Social Fund - COMPETE. Project “PEst-C/MAR/LA0015/2013”.
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Dedico este trabalho aos meus pais, amigos, peixes, namorada e todas a minhocas que matei para o realizar.
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o júri
presidente Professora Doutora Maria de Lourdes Pereira Professor Associado C/Agregação, Universidade de Aveiro
Doutora Joana Isabel do Vale Lourenço Bolseira de Pós-Doutoramento, Universidade de Aveiro
Professora Doutora Ruth Maria de Oliveira Pereira Professora Auxiliar Convidada, Universidade do Porto
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agradecimentos
Queria agradecer a todas a pessoas que tornaram possível a realização deste trabalho. Às minhas orientadoras, Professora Doutora Ruth Pereira e Sónia Mendo, pela oportunidade, ajuda e confiança disponibilizada. Agradeço à Doutora Joana Lourenço e Doutor Sérgio Marques pela paciência e tempo disponibilizados para a realização deste projeto. À Ana Gavina, pela ajuda imprescindível durante o meu trabalho prático. À boa disposição e simpatia de todas as pessoas dos laboratórios onde trabalhei, em Aveiro e no Porto, para a realização deste trabalho. À minha namorada Sónia pela grande ajuda e apoio na correção da minha tese. Aos meus amigos que tiverem de prescindir da minha companhia durante algum tempo. Um agradecimento especial aos meus pais, que sempre me disponibilizaram as melhores condições e apoio para a realização do meu trabalho.
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palavras-chave
minhocas, Eisenia andrei, nanopartículas, nanomateriais,genotoxicidade, comet assay, stress oxidativo, enzimas antioxidantes,TiSiO4, SDS/DDAB
resumo
Nos últimos anos tem-se verificado um enorme crescimento da indústria da nanotecnologia. O aumento da produção e descoberta de novos nanomateriais, onde as nanopartículas estão incluídas, leva a um acréscimo do risco da introdução destes no ambiente. Apesar de recentemente se ter verificado um aumento da publicação de estudos relativos aos potenciais efeitos tóxicos destes materiais, estes são manifestamente insuficientes devido à enorme diversidade de nanomateriais. Apesar da elevada importância dos solos, existe uma falta de estudos sobre este compartimento. Como tal, mais estudos sobre os potenciais efeitos nefastos dos nanomateriais no solo são necessários. Para estudos de toxicidade de partículas no solo, as minhocas são um organismo indicado. Estas têm sido usadas durante mais de 30 anos em exposições a contaminantes no solo e são consideradas um organismo essencial para a manutenção deste compartimento. O nosso trabalho teve como objetivo determinar se diferentes concentrações de dois tipos distintos de nanopartículas, uma inorgânica (titanium silicon oxide -TiSiO4) e outra orgânica (sodiumdodecylsulphate/didodecyldimethylammoniumbromide - SDS/DDAB), são genotóxicas e também se desencadeiam uma resposta antioxidante em organismos terrestres. Para tal, minhocas da espécie Eisenia andrei foram expostas durante 30 dias a solos artificiais “Organisation for Economic Co-operation and Development” (OECD) contaminados com diferentes concentrações das nanopartículas teste. Após a exposição, coelomócitos foram extraídos das minhocas e os danos no DNA foram quantificados usando o “comet assay”. A atividade das enzimas antioxidantes (glutationa S-Transferase, glutationa peroxidase e glutationareductase), bem como produtos da peroxidação lipídica, foram determinados. Os resultados mostraram que ambas as nanopartículas são genotóxicas, em especial o TiSiO4. Tendo em conta a literatura disponível seria esperado que esta genotoxicidade estivesse relacionada com um aumento na produção de espécies reativas de oxigénio, levando a alterações significativas na atividade de enzimas antioxidantes e na peroxidação lipídica, mas tal não se verificou. Foi possível verificar alterações na actividade de algumas enzimas e na peroxidação lipídica nos tratamentos com as NPs, mas estas alterações não foram estatisticamente significativas. Os nossos resultados sugerem que ambas as nanopartículas são capazes de levar a danos no DNA aparentemente não relacionado com o stress oxidativo.
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keywords
earthworms, Eisenia andrei, nanoparticles, nanomaterials, genotoxicity, comet assay, oxidative stress, antioxidant enzymes, TiSiO4, SDS/DDAB
abstract
In the last few years there has been a growth in the nanotechnology industry. The increase in the discovery and production of new nanomaterials, were the nanoparticles are included, makes their release in the environment more likely. Although in the recent years there has been an increase of published studies related to the toxic effects of these materials, the information available is not enough since a large number of nanomaterials exist. Even though the soils are extremely important for life, there is a lack of toxicity studies available. Taking this in consideration, more studies using the terrestrial compartment are needed. For these studies, earthworms are a recommend species since standard guidelines for toxicity tests in soil using earthworms have been used with success for more than 30 years and this species is essential for the maintenance of properties of this compartment. The aim of our work was to determine if different concentrations of two distinct types of nanoparticles, one inorganic (titanium silicon oxide- TiSiO4) and other organic (sodium dodecyl sulphate/didodecyldimethylammonium bromide- SDS/DDAB), are genotoxic and also if there is an antioxidant response in terrestrial organisms. For this, earthworms from the species Eisenia andrei (weight: from 300 to 600mg) were exposed for 30 days to the“Organisation for Economic Co-operation and Development”(OECD) artificial soil contaminated with different concentrations of the tested nanoparticles. After the exposure, coelomocytes were extracted from earthworms and DNA damage was assessed by comet assay. In addition the activity of antioxidant enzymes (e.g. glutathione peroxidase, glutathione reductase and glutathione-S-Transferase) was assessed, as well as lipid peroxidation. The results have shown that both particles were genotoxic, specially the TiSiO4-NPs. Taking in consideration available information about the mechanism by which the nanoparticles can exert their toxicity, it was expected that the genotoxicity would be related with an increase with the production of reactive oxygen species,leading to alterations in the activity of the antioxidant enzymes and the products of lipid peroxidation. Although some alterations could be found in the activity of antioxidant enzymes and in lipid peroxidation, these results are not statistically significant, suggesting that both nanoparticles are capable of causing damage to the DNA, but the mechanism used by these particles might not related with oxidative stress.
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Index
Chapter 1 - General Introduction
1.1. Nanomaterials (NMs): Definition and classes 19
1.2. Nanomaterials: Uses and risks of introduction in the environment 20
1.3. Nanomaterials: Nanoparticles sources, properties and mechanism of
genotoxicity 22
1.4. Test organism and genotoxicity and oxidative stress biomarkers 25
1.5. Test nanoparticles 27
1.5.1. Titanium silicon oxide nanoparticles (TiSiO4-NPs) 27
1.5.2. Sodium dodecyl sulfate/Didocyldimethylammonium bromide
nanoparticles (SDS/DDAB-NPs)
28
2. Purpose of the study 29
3. References
30
Chapter 2 - Evaluation of the genotoxicity effect and antioxidant response to
titanium silicon oxide in Eisenia andrei
1. Introduction 41
2. Material and Methods 44
2.1. Test soil 44
2.2. Test organism 44
2.3. Tested nanomaterial 44
2.4. Test procedure 45
2.5. DNA damage quantification 47
2.5.1. Non-invasive coelomocytes extrusion 47
2.5.2. Comet assay 47
2.5.2.1. Slide preparation 47
2.5.2.2. Image analysis 48
2.6. Biochemical analysis 49
2.6.1. Preparation of the samples 52
2.6.2. Protein quantification 52
2.6.3. Determination of lipid peroxidation 52
2.6.4. Determination of the activity of Glutathione Reductase 52
2.6.5. Determination of the activity of Glutathione S-Transferases 52
2.6.6. Determination of the activity of Glutathione Peroxidase (selenium
and non-selenium dependent)
53
2.7. Statistical analysis 53
3. Results 53
3.1. Effects of TiSiO4 nanoparticles in the DNA of earthworms 54
3.2. Biochemical Analysis 54
4. Discussion 58
5. Conclusions 61
6. References
63
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Chapter 3 - Evaluation genotoxic effect and antioxidant response to vesicles
composed of sodium dodecyl sulphate/didodecyldimethylammonium bromide in
Eisenia Andrei
1. Introduction 73
2. Material and Methods 76
2.1. Test soil 76
2.2. Test organism 76
2.3. Tested nanomaterial 76
2.4. Test procedure 77
2.5. DNA damage quantification 79
2.6. Biochemical analysis 79
2.7. Statistical analysis 79
3. Results 79
3.1. Effects of SDS/DDABnanoparticles in the DNA of earthworms 80
3.2. Biochemical Analysis 81
4. Discussion 84
5. Conclusions 86
6. References
87
Chapter 4 – General discussion and conclusion
General discussion and conclusion 93
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List of abbreviations
ANOVA – analysis of variance
ASTM – american society for testing and materials
CAT – catalase
CDNB – 1-chloro-2,4-dinitrobenzene
DDAB–didocyldimethylammonium bromide
DNA – deoxyribonucleic acid
EDTA – Ethylenediaminetetraacetic acid
FETAX – the frog embryo teratogenesis assay xenopus
GPx – glutathione peroxidase
GRED – glutathione reductase
GST – glutathione s-transferase
MDA – malondialdehyde
NADPH – nicotinamide adenine dinucleotide phosphate
NM(s) – nanomaterial(s)
NMP – normal melting point
NP(s) – nanoparticle(s)
OECD – organization for economic co-operation and development
PBS – phosphate buffered saline
RNA – ribonucleic acid
ROS – reactive oxygen species
SCGE – single cell gel electrophoresis
SDS –sodium dodecyl sulfate
SDS/DDAB – sodium dodecyl sulfate/didocyldimethylammonium bromide
SOD – superoxide dismutase
TBARS – thiobarbituric acid reactive substances
TiSiO4 – titanium silicon oxide nanoparticles
Tris-HCl – trishydroxymethylaminomethane hydrochloride
WHC – water holding capacity
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List of figures and tables
Figures
Chapter 1
Figure 1: Number of consumer products available that make use of nanotechnology over
the last years (“http://www.nanotechproject.org/cpi/about/analysis/”).
Figure 2: Some of the possible routes by which the nanomaterials might enter the
environment (Dowling, Clift, Grobert, & Hutton, 2004).
Figure 3: Possible sources of reactive oxygen species and the antioxidant defenses
involved in maintaining stable levels of these species. Effects of the alterations on the
homeostasis are also shown (Finkel & Holbrook, 2000).
Chapter 2
Figure 1: Schematic representation of the test procedure used in the exposition of the
earthworms to TiSiO4 nanoparticles.
Figure 2: Flask with earthworms inside being depurated.
Figure 3: The five classes used in the visual scoring of comets. The 0 represents cells with
no damage and 4 represents cells with extreme damage in DNA. The 1 to 3 classes
represent intermediary values of DNA damage(Collins, 2004).
Figure 4: Representation of the 96 well flat bottom plates used in the analysis of the
biomarkers.
Figure 5: Illustration of the Microplate reader used during the analysis of the biomarkers.
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Figure 6: Centrifuge used in the centrifugation of the homogenates.
Figure 7: A simple scheme of the steps used in the preparation of a samples for the
biochemical analysis.
Figure 8: Mean DNA damage score, show in arbitrary units, for each treatment. A ***
above the bar indicates statistically significant differences between the treatment and the
control (F = 12.77, df1=12, df2 = 22, p < 0.001). The error bars represent the standard
error.
Figure 9: Mean content of TBARS for each treatment. The error bars represent the
standard error.
Figure 10: Mean activity of GRED for each treatment. The error bars represent the
standard error.
Figure 11: Mean activity of GST for each treatment. The error bars represent the standard
error.
Figure 12: Mean activity of selenium-dependent GPx for each treatment. The error bars
represent the standard error.
Figure 13: Mean activity of total GPx for each treatment. The error bars represent the
standard error.
Figure 14: Cellular uptake of NPs and possible routes of genotoxicity (Magdolenova et al.,
2014).
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Chapter 3
Figure 1: Schematic representation of the test procedure used in the exposition of the
earthworms to SDS/DDAB nanoparticles.
Figure 2: Flask with earthworms inside being depurated.
Figure 3: Mean DNA damage score, show in arbitrary units, for each treatment. A **
above the bar indicates statistically significant differences between the treatment and the
control (F = 4.403, df1 = 5, df2 = 18, P = 0,009). The error bars represent the standard
error.
Figure 4: Mean content of TBARS for each treatment. The error bars represent the
standard error.
Figure 5: Mean activity of GRED for each treatment. The error bars represent the standard
error.
Figure 6: Mean activity of GST for each treatment. The error bars represent the standard
error.
Figure 7: Mean activity of selenium-dependent GPx for each treatment. The error bars
represent the standard error.
Figure 8: Mean activity of total GPx for each treatment. The error bars represent the
standard error.
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Tables
Chapter 1
Table 1:Summary of the natural and anthropogenic sources of nanoparticles(Oberdörster,
Oberdörster, & Oberdörster, 2005)
Chapter 2
Table 1: Summary of the information available about the toxicity of TiSiO4 nanoparticles
indicating the used organism(s), exposure medium, exposure duration, concentration of
TiSiO4 in medium, and results.
Chapter 3
Table 1: Summary of the information available about the toxicity of SDS/DDBA
nanoparticles indicating the used organism(s), exposure medium, exposure duration,
concentration of SDS/DDBA in medium, and results.
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Chapter 1
General Introduction
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1. General Introduction
1.1. Nanomaterials (NMs): Definition and classes
At the end of 1959, the physicist Richard Feynman suggested that a field not well explored
by that time should be taken in consideration. The field he was talking about was the
manipulation of things at a smaller scale[1]. Thanks to his ideas, some years later, the term
Nanotechnology was created[2].
Although 55 years have passed, there is still a debate going on regarding the
nomenclature associated with Nanotechnology and Nanoscience[3]. Using the definition
from The Royal Society & The Royal Academy of Engineering and The Nanoscale Science,
Engineering, and Technology Organization we can say that Nanoscience is usually
associated with the study of materials at the nanoscale (from 0.2 to 100 nm), while the term
Nanotechnology is often related to the manipulation and creation of things in that scale[2],
[4]. In our work, a distinction between these two terms was not made since they both deal
with materials at the nanoscale level. The major concern in these two fields is the
production and the discovery of different types of NMs with new and/or improved
properties[4]. The Directorate-General for the Environment from the European
Commission defines a NM as “a natural, incidental or manufactured material containing
particles, in an unbound state or as an aggregate or as an agglomerate and where, for 50 %
or more of the particles in the number size distribution, one or more external dimensions is
in the size range 1 nm - 100 nm.”. They also added that in some cases the NMs can have a
distribution threshold between 1 – 50 % and a size inferior to 1nm[5].
The United States Environmental Protection Agency groups the NMs in three types
according to their source: naturally occurring (e.g. volcanoes and forest fires), produced by
human activity unintentionally (e.g. automobile exhaust) or intentionally (engineered
NMs). This agency has taken a special interest in the engineered NMs, defining four major
groups based on their chemical composition and physical structure: Carbon-based,
dendrimers, metal-/metal oxide-based, and quantum dots[6].
The carbon-based NMS, as their name suggests, contain mainly or only carbon in
their constitution. These NMs have unique conductivity and thermal properties.
Dendrimers are branched molecules that repeat themselves around a core internal cavity
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were other molecules can be present. NMs based on metal-/metal oxides are composed
totally or partially by one or more metals. These NMs have a large range of optical,
thermal, magnetic, and conductivity properties. Quantum Dots are semiconductors with
special electrical and optical properties[6].
The Royal Society & The Royal Academy of Engineering uses another type of NMs
classification according to the dimensions they have at the nanoscale: thin films, layers,
and surfaces only have one dimension at the nanoscale and other two dimensions extended;
carbon nanotubes and nanowires have two dimensions at the nanoscale and one is
extended; nanoparticles (NPs) have three dimensions at the nanoscale[4].
1.2. Nanomaterials: Uses and risks of introduction in the environment
The NM industry has a large potential that keeps growing year after year[7]. In 2012, 18.5
billions of american dollars have been invested in the development of this area and
research estimates a revenue of 4.4 trillion of American dollars by 2018[8]. In October
2013, The Project on emerging Nanotechnologies listed 1628 consumer products that made
use of Nanotechnology (Figure 1). Most of the products listed are related to health and
fitness (788 products), home and garden (221 products) and food and beverage (194
products). The most used materials were silver, titanium and carbon[9].
The constant growth on the use of NMs and the applications that they have makes
their release into the environment inevitable. Although manufactured NMs are released
intentionally in the environment for remediation of soils and water, risk of contamination
can also come from the discharge/leakage of the materials during their transport, storage,
and production[3], [4]. Since NMs have a large range of applications, it is expected that in
the near future these particles can enter the environment by other means (e.g. release by
domestic effluent or hospital activities). After their release in the environment, the NMs
can possibly interact with the biota (Figure 2)[3]. The environmental matrix (e.g. soil and
water) were the NMs are released is extremely important when it comes to the potential
toxicity of the materials. Abiotic factors like pH, ionic strength, and water hardness can
influence the behavior of the NMs and their access to the organisms (e.g. formation of
aggregations or alterations in the NMs properties)[10].
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The three main routes that NMs can access the human body include inhalation of
the materials by air, direct contact (dermal absorption) and ingestion. The use of sprays
with NMs (e.g. sunscreens, hairsprays, and pesticides) can result into their incorporation by
inhalation and the exposition of the respiratory tract. The use of textiles, creams, lotions,
and other products with NMs can lead to dermal absorption of these materials by the skin.
NMs used in food packages and supplements can gain access to the organism during their
ingestion[11]. It is important to take in consideration that not all the NMs pose the same
risk to the environment and organisms, factors like the toxicity, the time of the exposure
and the dose have to be taken into account[4].
Figure 1: Number of consumer products available that make use of nanotechnology over
the last years[9].
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Figure 2: Some of the possible routes by which the nanomaterials might enter the
environment[4].
1.3. Nanomaterials: Nanoparticles sources, properties and mechanism of genotoxicity
NPs are a class of NMs that have always existed in the environment and that are mostly
produced by natural sources. With the advancement of civilization more particles have
been fashioned inadvertently by human activities and with the advent of the
Nanotechnology more NPs are intentionally manufactured[12]. Table 1 summarizes the
types of NPs arranged in three classes based on their source (natural or anthropogenic).
Manufactured NPs show new properties that cannot be found in particles of the same
material with larger size[4]. The smaller size not only increases the relative surface area of
the particles making them more reactive, but it can also alter the material properties (e.g.
electrical conductivity and fluorescence color)[13]. Because of these properties, the NPs
have been used in diverse applications like cosmetics, textiles, paints, electronics, and
optical devices. In the future, some will be often used to specific drug delivery in the
body[4].
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Most of the NPs interacting with organisms during their lifetime can be considered
benign[14]. One of the biggest problems of the creation and manufacturing of new NPs is
that the effects of these particles on human health and other organisms are not well
understood. The characteristics that make the NPs so interesting can also be the reasons of
their potential toxicity (e.g. the smaller size can make the access to the cells easier and the
material more reactive)[15]. As previously stated, not all NPs are toxic, some of them are
only toxic when free (e.g. not fixed to an electric circuit) or for a limited period of time
(e.g. some NPs can be degraded or transformed in non-toxic forms)[14]. It is also possible
to find NPs that are beneficial to the exposed organisms (e.g. cerium and yttrium oxide
NPs acted as antioxidants and protected nerve cells from oxidative stress)[16]. To quantify
the toxicity and genotoxicity of the NPs, in addition to the size, one should also consider
other physical and chemical properties like the shape, crystalline structure, surface area and
properties, agglomeration, and solubility[15]. The environment matrix where they are
introduced (e.g. air, soil and freshwater) is also important[3].
Depending on the physical and chemical properties of the NPs, they can enter the
organism and the cells and be found on different locations (e.g. cytoplasm, mitochondria,
lipid vesicles, and near or inside the nucleus)[14]. These locations can probably influence
the type of the mechanism by which NPs can exert their genotoxicity[14]. Not much is
known about the mechanisms that make the NPs genotoxic. One of the possible tools of the
NPs toxicity is the direct interaction with Deoxyribonucleic Acid (DNA) that may cause
damage[15]. The NPs can also cause indirect damage to the DNA by interacting with
nuclear proteins, interfering on the cell cycle or by directly or indirectly increasing the
production of Reactive Oxygen Species (ROS)[15]. The oxidative stress caused by ROS
increase, that can lead to damage in lipids, proteins and DNA, is thought to be the main
mechanism of NPs genotoxicity[17]. The majority of the ROS are naturally produced in
the cell, mostly by the mitochondria and peroxisomes activity[18]. The levels of ROS are
maintained at a certain degree by a complex system of antioxidant enzymes like catalase
(CAT), superoxide dismutase (SOD) and glutathione peroxidase (GPx), and molecules like
glutathione[18]. A certain level of ROS is necessary to maintain the homeostasis but their
production can be increased by external sources like ultraviolet light and environmental
toxins (e.g. NPs) (Figure 3)[18]. An excess of ROS production, caused by the activity of
these external sources may overwhelm the antioxidant system, leading to a condition called
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oxidative stress. This stress might result in damage to the genetic material and, in some
cases, the death of the cell[19]. This damage can lead to strand breaks, deletions and
mutations in the DNA[20].
Table 1: Summary of the natural and anthropogenic sources of nanoparticles[12].
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Figure 3: Possible sources of reactive oxygen species and the antioxidant defenses
involved in maintaining stable levels of these species. Effects of the alterations on the
homeostasis are also shown[18].
1.4. Test organism and genotoxicity and oxidative stress biomarkers
With the growth of the Nanotechnology industry, it is only a matter of time before NPs are
introduced in the soil. Not much is known about the potential effects of these particles in
the terrestrial ecosystems[3]. Soils are extremely important for life because they support
plants growth and habitats for a wide variety of organisms and are also essential for the
human economy[21].
To test the ecotoxic effects of NPs in soil organisms, an indicator test species is
necessary. Earthworms are extremely important for terrestrial ecosystems, being known as
the “engineers of soil”. They are essential for the normal operation of this compartment,
carrying out crucial functions such as maintaining the soil permeability and aeration,
degradation of organic matter, and mixture of soil minerals[22]. Earthworms of the species
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Eisenia andrei (Bouché, 1972) are recommended as test species in soil. Standard
guidelines have been developed and used for more than 30 years to test possible toxic
effects of contaminants in soils[23]. These earthworms are ubiquitous, having a worldwide
distribution. They are tolerant to a good range of temperatures and moistures and are easy
to handle. They can be fed with animal manure or oatmeal. Their life expectancy can go up
to five years, but they usually live two years or less depending on the soil conditions. Their
life cycle is short, being around 45 – 51 days under optimal conditions[24].The
earthworms Eisenia andrei/fetida have also been used before in ecotoxicity tests, using
NPs like TiO2, ZnO, Cu, Ag, Au, Al2O3,Ni, SiO2, ZnO2, and CeO2[17], [25]–[29]. Most of
these studies were based on standard toxicity tests using mortality and reproduction rates
as indicators of toxicity. Even though these indicators are useful, the information given by
them is somewhat limited[30]. NPs can have a negative result on these standard toxicity
tests, but a closer look at the genetic material may reveal alterations. This may lead, on the
long term, to an impairment of the organism fitness and alterations in the ecosystem[17].
Since some NPs are potentially genotoxic, using genotoxicity biomarkers like DNA
damage and oxidative stress biomarkers, like alterations in the activity of enzymes
involved in the antioxidant response, is recommended[17], [30].
The single cell gel electrophoresis, known as the comet assay, is one of the most
used tests for genotoxicity[15]. This method allows the measure of DNA damage and
recruited many followers thanks to its “simplicity, sensitivity, versatility, speed, and
economy”[31].
Alterations in the production of ROS and the antioxidant system can result in a
condition called oxidative stress that can randomly damage molecules in the cell like DNA,
proteins and lipids[18]. Since this condition leads to modifications in lipid peroxidation
and the antioxidant system, these two markers can be use as biomarkers of oxidative
stress[32].
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1.5. Test nanoparticles
1.5.1. Titanium silicon oxide nanoparticles (TiSiO4-NPs)
The thermal and electrical properties of these inorganic NPs have aroused the interest of
the Nanotechnology industry. These particles are being used in a diverse range of products,
therefore there is an increase risk of environment introduction in the future[3].
To our knowledge, only four studies are available about the ecotoxicology of these
NPs.
The studies of Pereira et al.[33]and Lopes et al.[34] used the bacterium Vibrio
ficheri (Microtox assay) to test the toxicity and two strains of Salmonella typhimurium
(Ames assay) to test the genotoxicity of TiSiO4-NPs. The first study was done with soil
spiked with a suspension of TiSiO4-NPs, with a desired concentration of 5 grams of NPs
per kilogram of soil. Soil matrix and soil elutriates were sampled and tested with Microtox
and Ames assays (only used on soil elutriates) after 2 hours and after 30 days. This study
revealed that TiSiO4-NPs are not toxic after 2 hours or 30 days but they can be genotoxic
especially after 30 days of exposure[33]. In the second study, TiSiO4-NPs were suspended
in two different types of aqueous media with different properties - Milli Q water and
American Society for Testing and Materials (ASTM) water (ASTM water was not used in
the Ames assay). Five grams of TiSiO4 were added per liter of medium. The assays
revealed that the TiSiO4-NPs are only toxic in Milli Q water and that they are not
genotoxic[34].
In another work, done by Nogueira et al.[35], soils were spiked and incubated for
30 days with TiSiO4-NPs in an aqueous media (5 g of TiSiO4-NPs per kg of soil). The aim
of the study consisted in assessing the alterations of the structure of the soil bacterial
community. The study revealed that the bacterial community did not suffer significant
changes from the exposition to TiSiO4-NPs[35]. Salvaterra et al.[36] exposed tadpoles of
Pelophylax perezi to five different concentrations (8.2, 10.2, 12.8, 16, and 20 mg/L) of
TiSiO4-NPs in The Frog Embryo Teratogenesis Assay Xenopus (FETAX) medium during
96 hours. In this study, the mortality and other biochemical markers were analyzed and the
results showed that the mortality of the tadpoles did not suffer significant changes.
However on the biochemical level, some alterations could be found in the catalase and
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28
lactate dehydrogenase activity and lactate and alanine contents, suggesting that TiSiO4-
NPs can lead to oxidative stress[36].
In all the works reported, the TiSiO4-NPs showed a tendency to form large
aggregates in aqueous suspensions.
1.5.2. Sodium dodecyl sulfate/Didocyldimethylammonium bromide nanoparticles
(SDS/DDAB-NPs)
Vesicles of SDS/DDAB are not yet commercialized but, given their potential applications
in medicine and cosmetics, it is only a matter of time before they are used and introduced
into the environment[34].
To our knowledge, only four studies are available about the ecotoxicology of these
NPs.
Pereira et al.[33] and Lopes et al.[34] used the Microtox and the Ames assay to test
respectively the toxicity and genotoxicity of SDS/DDAB-NPs. The first assay makes use
of the bacteria Vibrio ficheri and the second one uses two strains of the bacteria Salmonella
typhimurium (TA98 and TA100)[33], [34] Pereira et al.[33] spiked soils with aqueous
suspensions of SDS/DDAB-NPs and found that soil and soil elutriates were very toxic
after 2 hours and after 30 days. Using soil elutriates, they also found that SDS/DDAB-NPs
are genotoxic to the strain TA98 of Salmonella typhimurium after 30 days[33]. Lopes et
al.[34] used aqueous suspensions of SDS/DDAB-NPs. For the Microtox assay they used
two different mediums for aqueous suspensions (Milli Q water and ASTM water) and for
the Ames assay they only used Milli Q water. Toxicity was found using both waters as
mediums and genotoxicity was found on the strain TA98 of Salmonella typhimurium[34].
Nogueira et al.[35] spiked the soil with SDS/DDAB-NPs suspensions and analyzed
it after 30 days to see if alterations on soil bacterial community could be found. Their study
revealed that SDS/DDAB-NPs can lead to alterations in the community composition.
Galindo et al.[37] used on their work four types of white-rot fungi - Trametes versicolor,
Lentinus sajor caju, Pleurotus ostreatus and Phanerochaete chrysosporium. Five
concentrations SDS/DDAB-NPs were suspended in an aqueous media and disposed evenly
in agar. The growth of the fungi was measured every day to test the toxicity of the NPs
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29
suspension. All the tested concentrations significantly affected the growth of the four types
of white-rot fungi[37].
All the previous works, except for Galindo et al.[37] reported a high stability of
SDS/DDAB-NPs meaning that large aggregates are not expected and were not found[33]–
[35].
2. Purpose of the study
The aim of our work was to find if soils contaminated with TiSiO4 and SDS/DDBA NPs
are genotoxic to the earthworms from the species Eisenia andrei and also if this toxicity is
related to an antioxidant response. For this, earthworms were maintained for 30 days in soil
contaminated with different concentrations of these two NPs. After the exposure,
genotoxicity biomarkers like DNA damage and oxidative stress biomarkers like alterations
in the activity in enzymes related to antioxidant response and products of lipid
peroxidation were assessed.
From the information available in the literature, it is expected that possible DNA
damage caused by these two NPs will be associated with alterations in the activity of
enzymes related to antioxidant response and products of lipid peroxidation.
The present thesis is organized in four chapters:
Chapter 1 – General introduction to nanomaterials, nanoparticles, test species,
tested nanoparticles, and purpose of the study.
Chapter 2 – Evaluation of the genotoxicity effect and antioxidant response to
titanium silicon oxide in Eisenia andrei.
Chapter 3 – Evaluation of the genotoxicity effect and antioxidant response to
vesicles composed of sodium dodecyl sulphate/didodecyl dimethylammonium
bromide in Eisenia andrei.
Chapter 4 – General discussion and conclusion.
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30
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Chapter 2
Evaluation of the genotoxicity effect and
antioxidant response to titanium silicon oxide
in Eisenia andrei
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Evaluation of the genotoxicity effect and antioxidant response to titanium
silicon oxide in Eisenia andrei
Abstract
In the last few years there has been a fast growth in the nanotechnology related products.
Since some of these materials are relatively new, not much information is available about
their potential harmful effects to the environment, and when it comes to titanium silicon
oxide nanoparticles (TiSiO4-NPs), even less studies are available. With this work we
sought to determine whether different concentrations ofTiSiO4-NPs are genotoxic and also
if there is an antioxidant response in terrestrial organisms. Eisenia andrei was the selected
species, since they are essential for the maintenance of soil properties and also because
they are recognized as a model species in soil toxicity and have been used for more than 30
years in toxicity tests. For this purpose, earthworms (weight: 300 - 600mg) were exposed
for 30 days to the OECD artificial soil contaminated with different concentrations of
TiSiO4-NPs. After the exposure, coelomocytes were extracted from earthworms and DNA
damage was assessed by comet assay. In addition the activity of antioxidant enzymes (e.g.
glutathione peroxidase, glutathione reductase and glutathione-S-Transferase) was assessed,
as well as lipid peroxidation. Statistical analysis revealed that organisms exposed to the
highest concentrations of TiSiO4 (≥ 444.4 mg of NPs per kg of soil) have damage in the
DNA when compared to the control. Although some tendencies could be observed, no
significant alterations on the antioxidant enzymes or lipid peroxidation were found. Our
results suggest that the TiSiO4-NPs are able do damage the DNA. With our tested
concentrations and time of exposure no alterations were found on the oxidative stress
biomarkers suggesting that the DNA damage found might not be related with oxidative
stress.
Keywords: Earthworms, comet assay, DNA damage, TiSiO4, antioxidant enzymes,
oxidative stress, nanoparticles
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1. Introduction
Titanium silicon oxide (TiSiO4) NPs can be used in different areas of the industry.
For example, these NPs can be applied as a catalyst agent in pyrolysis[1], [2], in the
production of more efficient thermosyphons[3], antireflective coatings, notch filters,
optical devices, electric components (semiconductors and capacitors)[4], [5], composite
membranes for fuel cells[6], [7] and also as pharmaceutical and cosmetic excipients[8].
The nanotechnology industry has grown exponentially in the past years[9]. A great
number of new NMs have been created and more will probably be discovered and used in
the future. This growth will lead to an increase risk of introduction of the NMs in the
environment that can interact with the biota[10].
Although in the last few years there has been a great increase in the number of
published studies about the toxicity of the NPs[11], only few works reported the potential
toxic effects of TiSiO4-NPs. In addition, the results presented by the authors are not
consensual[12]–[15]. Table 1 has a brief description of what is known about the toxicity
and genotoxicity of these particles.
In the case of TiSiO4-NPs, we have the same number of studies published about the
impact in the soil and aquatic compartment, but, when talking about studies of other NMs,
there is a higher tendency to find studies about the aquatic compartment when compared
with the soil compartment[12]. Having this in consideration, it is important to obtain more
information about the effects of NPs and TiSiO4-NPs in special on the soil compartment.
In the present study, earthworms from the species Eisenia andrei were exposed to
soils contaminated with different concentrations of TiSiO4-NPs for 30 days. There are
standard guidelines to test toxicity in earthworms developed by environmental
organizations for more than 30 years[16] and earthworms are recognized has one of the
most important members of the terrestrial ecosystems[17]. Earthworms from the species
Eisenia andrei have a ubiquitous worldwide distribution, are tolerant to a large range of
temperatures and moistures, they are easy to handle, and have a short life cycle making
them a recommended test species for soil ecotoxicity tests[18].
NPs can cause direct damage to DNA or can directly or indirectly increase the
production of ROS, which change proteins, lipids and DNA[19]. Having this in
consideration, we used genotoxicity biomarkers like DNA damage. The damage was
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42
measured using an alkaline version of the comet assay. Since this is assay is “simple,
sensitive, versatile, fast, and cheap” it has become the most used genotoxicity tests for
NPs[19], [20] and was used in our work. Oxidative stress biomarkers like alterations in the
activity of enzymes as Glutathione Reductase (GRED), Glutathione S-Transferase (GST)
and Glutathione Peroxidase (GPx) implied in the antioxidant response, and the
determination of Thiobarbituric Acid Reactive Substance (TBARS) that results from an
increase of lipid peroxidation during stress conditions[21] were also used in our work with
aid of spectrophotometry. The objective was to see if DNA damage could be found and if
it is related with alterations in the oxidative stress biomarkers.
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Table 1: Summary of the information available about the toxicity of TiSiO4 nanoparticles indicating the used organism(s), exposure medium,
exposure duration, concentration of TiSiO4 in medium, and results.
Reference Organism(s) Exposure medium Exposure
duration
Concentration of
TiSiO4 in medium Results
[13]
Vibrio ficheri
Salmonella typhimurium(Strain
TA98 and Strain TA100)
Soil contaminated with
aqueous suspension of
TiSiO4
2 hours and 30
days 5g/kg
Microtox assay (Vibrio ficheri) revealed
no toxicity after the 2 hours and 30 days
exposition.
The Ames (Salmonella typhimurium)
assay revelead genotoxicity after 30 days
in both strains.
[14]
Vibrio ficheri
Salmonella typhimurium(Strain
TA98 and Strain TA100)
TiSiO4 suspended in two
aqueous media N/A 5g/l
Microtox assay (Vibrio ficheri) revealed
that suspensions in Milli Q water are
toxic.
The Ames (Salmonella typhimurium)
assay revealed no genotoxicity.
[12] Soil microbial community
Soil contaminated with
aqueous suspension of
TiSiO4
30 days 5g/kg No alterations in the structural diversity
of the soil microbial community.
[15] Pelophylax perezi
TiSiO4 suspended in
aqueous media (FETAX
solution)
96 hours 8.2; 10.2; 12.8; 16 and
20 mg/L
Reduction in lactate and alanine
concentrations.
Increase in activity of catalase and LDH
activity for some concentrations.
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2. Material and Methods
2.1. Test soil
The standard artificial Organization for Economic Co-operation and Development
(OECD) soil was used in this work[16]. This soil has approximately the following
constitution: 75% industrial sand, 20% kaolin and 5% of sphagnum peat (5 mm sieved).
The pH of the soil was adjusted to 6.0±0.5 using calcium carbonate. To assess the Water
Holding Capacity (WHC), samples of the soil were inserted in flasks with the bottom
removed and replaced with filter paper. These flasks were immersed for two to three hours
in water. After the immersion, the weight of the soil was assessed. After that the soil was
dried for 24 hours at 105ºC and the weight was measured again. To determine the WHC
the difference between the two weights was used[22].
2.2. Test organism
Earthworms of the species Eisenia andrei were used on this study. The organisms were
obtained from laboratorial cultures under controlled conditions: temperature of 21ºC and
photoperiod of 16 hours of light and 8 hours of dark. Once a week, the earthworms in
culture were feed horse manure or oatmeal. From the cultures, 240 earthworms with a body
mass between 300 and 600 mg were washed with deionized water and let to acclimatize in
containers containing OECD soil for 24 hours.
2.3. Tested nanomaterial
In this work, the TiSiO4-NPs were obtained in a powder state. The NPs were supplied by
Sigma Aldrich and had the following specifications: particles size less than 50 nm and
99.8% of purity.
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45
2.4. Test procedure
In this study, five concentrations of TiSiO4 were tested: 197.5, 296.3, 444.4, 666.7, and
1000.0 mg/kg. We named the concentrations respectively as 1, 2, 3, 4, and 5. A control
with only OCDE soil was also used. For each concentration and control, four replicas were
used. For the exposure, 24 buckets with pierced lids with an approximate volume of 0.6 L
were used. In each bucket, 500 g of OECD soil were added followed by the addition of
TiSiO4 powder to match the desired concentration. After this, the soil was homogeneously
mixed. Deionized water matching 40% of the WHC was added and we mixed the soil
again. The 240 earthworms previously acclimatized were cleaned with deionized water.
Ten earthworms with a mass between 300 and 600 mg were added to each bucket. Five
earthworms, randomly collected in each replicate, were used for the DNA damage
quantification and the other ones for the biochemical analysis. In Figure 1 we have a quick
illustration of this procedure. The 24 buckets with the 240 earthworms were incubated for
30 days in controlled conditions (temperature of 21ºC and a photoperiod of 16 hours of
light and 8 hours of dark). Once a week, oatmeal was used to feed the earthworms.
After the 30 days exposure, the earthworms were removed from the soil and
washed with deionized water. The earthworms from each exposure bucket were transferred
and depurated for 24 hours on smaller recipients (making a total of 24 smaller recipients)
with filter paper in the bottom embedded with deionized water (Figure 2). Earthworms
used for the DNA damage quantification were used on the same day and the other ones
were frozen in nitrogen and stored at -80 ºC.
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46
Figure 1: Schematic representation of the test procedure used in the exposition of the
earthworms to TiSiO4 nanoparticles.
Figure 2: Flask with earthworms inside being depurated.
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47
2.5. DNA damage quantification
For the DNA damage quantification we used the Single-Cell Gel Electrophoresis (SCGE),
also known as comet assay. This method has become a standard when it comes to the
assessment of DNA damage[20] and it is the most used technique in genotoxicity studies
related to NPs[19]. Coelomocytes from earthworms have been used before with the comet
assay for the detection of genotoxic compounds in soils, thus they were also used in this
work[23].
2.5.1. Non-invasive coelomocytes extrusion
The coelomocytes were obtained from the earthworms using an adapted protocol from
Reinecke et al.[24] and Eyambe et al.[25]. For the extrusion, a solution containing
Phosphate Buffered Saline (PBS), ethanol and Ethylenediaminetetraacetic acid (EDTA)
was distributed between 24 Eppendorf tubes (one for each exposition bucket). In each
Eppendorf the earthworms were introduced and removed separately on periods of one
minute. Ethanol was used to aid the extrusion of the cells. The Eppendorfs containing the
cells and the extrusion fluid were centrifuged and the supernatant was removed to obtain a
cell pellet. This pellet was placed in new Eppendorfs and stored in ice.
2.5.2. Comet assay
The alkaline version of the comet assay followed the protocol used by Lourenço et al.[26].
All the steps were performed under yellow light to reduce the possible extra UV-induced
damage.
2.5.2.1. Slide preparation
Microscopes slides (one for each sample) were identified and covered with 1% Normal
Melting Point agarose (NMP) and let to dry overnight. From each Eppendorf containing
the cell suspensions (24 Eppendorfs), 10 μL (containing cells) were mixed with 0.5% low
melting point agarose and added to the top of each microscope slide containing NMP
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48
agarose. Ice was used to aid the solidification of the microscope slides. After the
solidification the slides were immersed for 24 hours in a lysing solution (2.5M NaCl,
100mM EDTA, 10mM Tris hydroxymethyl aminomethane hydrochloride (Tris-HCl),
triton X-100, DMSO, pH set to 10 using NaOH, and deionized water). The microscope
slides were removed from the lysing solution and cleaned with PBS. After that they were
immersed in an electrophoresis buffer (0.2 M Na2EDTA, NaOH and deionized water) for
15 minutes. An electrophoresis was run for 10 minutes. After this the slides were washed
with Tris-HCl and submerged in absolute ethanol and left to dry. Each slide was stained
with 80 μL of ethidium bromide for DNA visualization on fluorescence microscope.
2.5.2.2. Image analysis
The exposition of the cells to the lysing solution leads to the formation of the nucleoid, a
structure composed mainly by Ribonucleic Acid (RNA), DNA and proteins. Damage to the
DNA can lead to strand breaks that can be detected using the comet assay. When we run
the electrophoresis, the DNA extends toward the anode. If the DNA has little to no
damage, the extension to the anode is smaller because the DNA is more compacted. More
damage leads to more strand breaks causing a relaxation of the DNA making the DNA
extend towards the anode, leading to the formation of the “tail” of the “comet”[20].
The stained microscope slides were observed in an Olympus BX60 Fluorescence
microscope. For each microscope slide, 100 cells were randomly selected and a visual
score corresponding to DNA damage was attributed to the cells. This score ranged from 0
(no damage) to 4 (extreme damage) arbitrary units. A cell with a 0 would have its entire
DNA on the “head” of the comet and no “tail” (0 in Figure 3). On the other hand, if the
DNA was mostly in the “tail”, we would give that cell a score of 4 arbitrary units (4 in
Figure 4). Figure 3 shows an example of the 5 classes used in visual scoring. The possible
score of each slide could range from 0 to 400 arbitrary units.
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49
Figure 3: The five classes used in the visual scoring of comets. The 0 represents cells with
no damage and 4 represents cells with extreme damage in DNA. The 1 to 3 classes
represent intermediary values of DNA damage[20].
2.6. Biochemical analysis
On the biochemical analysis of the biomarkers related oxidative stress, 96 well flat bottom
plates (Figure 4) were used and examined with a plate reader (Figure 5) and the
appropriate software. Previous to the analysis, the samples were prepared and the
necessary dilutions for each of the tested biomarker were determined. The determination of
the protein content on each sample was necessary to express the biomarkers in function of
this value.
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50
Figure 4: Representation of the 96 well flat bottom plates used in the analysis of the
biomarkers.
Figure 5: Illustration of the Microplate reader used during the analysis of the biomarkers.
2.6.1. Preparation of the samples
The earthworms from each sample were homogenized on phosphate buffer (50 mM, pH=
7.0 with 0.1% Triton X-100). Homogenates were centrifuged at 4 ºC and 15000 g for 10
minutes (Figure 6). After that, the supernatant was distributed between five Eppendorfs
(four for the biochemical analysis and another one as an extra) that were stored for later
use at -80ºC (Figure 7).
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Figure 6: Centrifuge used in the centrifugation of the homogenates.
Figure 7: A simple scheme of the steps used in the preparation of the samples for the
biochemical analysis.
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2.6.2. Protein quantification
To find the concentration of the protein in the tested samples in the microplates, an adapted
method from Bradford[27] was used. The reagent from Bradford BioRad forms a complex
with the proteins that allows their quantification at 595 nm. Bovine γ-globuline was used
as a standard. On each sample, the protein quantity was determined four times (four wells
used on the microplate).
2.6.3. Determination of lipid peroxidation
To determine the lipid peroxidation, the quantity of Thiobarbituric Acid Reactive
Substances (TBARS) was measured at 535 nm, using a modification of the protocol
described by Buege and Aust[28]. The results are expressed as nmol of peroxidation
products per mg of sample protein.
2.6.4. Determination of the activity of Glutathione Reductase
The activity of this enzyme was determined using a modified protocol from Carlberg and
Mannervik[29]. Spectophotometry was used to monitor the oxidation of Nicotinamide
Adenine Dinucleotide Phosphate (NADPH) by GRED at 340 nm. The activity was
expressed in μmol per minute per mg of sample protein.
2.6.5. Determination of the activity of Glutathione S-Transferases
The determination followed the protocol of Habig et al.[30]. In this assay, the activity of
the GST can be determined by the increase of the absorbance at 340 nm due to the
conjugation (catalyzed by the enzyme) of the substrate 1-chloro-2,4-dinitrobenzene
(CDNB) with glutathione and the formation of a thioter. The activity was expressed in
nmol per minute per mg of sample protein.
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2.6.6. Determination of the activity of Glutathione Peroxidase (selenium and non-
selenium dependent)
The enzyme Glutathione Peroxidase (GPx) is responsible for the oxidation of glutathione.
The oxidated glutathione is then reduced by glutathione reductase using NADPH.
According to Flohé and Günzler[31], the activity of GPx can be monitored following the
oxidation of NADPH at 340 nm. In this assay, two substrates used independently by the
GPx in the oxidation of glutathione were used – hydrogen peroxide and cumenehydro
peroxide. Selenium dependent GPx only uses hydrogen peroxide, cumenehydro peroxide
can be used by GPx selenium and non-selenium dependent. The activity of both enzymes
was expressed in nmol per minute per mg of sample protein.
2.7. Statistical analysis
To perform the statistical analysis, the software SigmaPlot 11.0 (United States, Systat
Software) was used. The objective of the study was to find if there were statistically
significant differences between the control group and the groups exposed to different
concentrations of TiSiO4-NPs. The data obtained from the DNA damage quantification and
the biochemical analyses were tested for normality (Shapiro-Wilk test) and homogeneity of
variance. One way analysis of variance (ANOVA) was used to test the differences between
the treatments and Dunnett’s tests were used to determine what treatments were different
from the control. A level of significance of 0.05 was chosen for rejecting the null
hypothesis.
3. Results
After the 30 days exposure, no mortality was found among the earthworms exposed to
different TiSiO4 treatments. During the depuration step, the earthworms from one of the
replicas with the concentration 3 (444.4 mg/Kg) escaped from the flask, leaving only 3
replicas for this tested concentration. Even on the highest concentrations, it was possible
to find earthworms cocoons in the soil, meaning that the presence of NPs did not inhibit
the reproduction of the earthworms.
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3.1. Effects of TiSiO4-NPs in the DNA of earthworms
The results obtained in the DNA damage quantification of the earthworms exposed to
different concentrations of TiSiO4-NPs are shown in Figure 8. A first look at Figure 8
reveals an increase of DNA damage with the elevation of the concentration of the NPs
tested. At the highest concentration, the mean damage score has doubled in comparison
with the control. Statistically significant differences (F = 12.77, df1 = 12, df2 = 22, p <
0.001) were found between earthworms exposed to the control and to concentrations equal
or superior to 444 mg/kg (concentrations 3, 4 and 5). No differences were found between
the control and the concentrations 1 and 2.
Figure 8: Mean DNA damage score, show in arbitrary units, for each treatment. A ***
above the bar indicates statistically significant differences between the treatment and the
control (F = 12.77, df1 = 12, df2 = 22, p < 0.001). The error bars represent the standard
error.
3.2. Biochemical Analysis
No statistically significant differences were found on the content of the TBARS (Figure 9),
suggesting that there were no alterations on the lipid peroxidation. Although there was a
*** ***
***
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55
tendency to the increase of the GRED activity, this growth was not significant for any of
the tested concentrations (Figure 10). Also, no significant differences were found for the
activity of the other tested enzymes: GST (Figure 11), GPx selenium-dependent (Figure
12) and total GPx (Figure 13). There was a decrease in the activity of the GPx selenium-
dependent with the increase of the TiSiO4 concentration, but it was not statistically
significant.
Figure 9: Mean content of TBARS for each treatment. The error bars represent the
standard error.
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56
Figure 10: Mean activity of GRED for each treatment. The error bars represent the
standard error.
Figure 11: Mean activity of GST for each treatment. The error bars represent the standard
error.
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Figure 12: Mean activity of selenium-dependent GPx for each treatment. The error bars
represent the standard error.
Figure 13: Mean activity of total GPx for each treatment. The error bars represent the
standard error.
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4. Discussion
Although in the last years there has been a growth in the NPs industry[9] and in the release
of studies about the potential toxic effects of these materials[11], not much information is
available about TiSiO4-NPs. Most of the studies available are related to genotoxicity of
silver and TiO2 NPs[19].
There is a lack of information about the way the NPs exert they genotoxicity. The
indirect damage of DNA by ROS is believed to be the main mechanism of NPs
genotoxicity[32]. ROS are needed to maintain physiological homeostasis but an increase in
ROS can lead to damage to proteins, lipids and DNA[21]. Studies about TiO2 and other
NPs have shown that these particles can lead to an increase of ROS and consequent DNA
damage[19]. The increase in ROS production is countered with an antioxidant system. Part
of this system is revolved around a molecule called glutathione and the enzymes GRED,
GST and GPx[21]. During the augment of stress by the production of ROS the lipid
peroxidation of the cell membranes also increases giving arise to products like
malondialdehyde (MDA)[32]. If the NPs could reach the nucleus or interact with it they
could possibly cause direct damage to the genetic material or indirect damage by
interacting with nuclear proteins or by interfering with the cell cycle[19]. In our work, we
used the DNA damage of the cells as biomarkers of genotoxicity and also oxidative stress
biomarkers like the alterations of the activity of antioxidant enzymes and products of lipid
peroxidation like MDA.
Our results showed that the exposition of earthworms to concentrations superior to
444 mg of TiSiO4-NPs per kg of soil can lead to significant increase of DNA damage,
suggesting that this NP is genotoxic as shown before by Pereira et al.[13]. For the higher
concentration (1000 mg of TiSiO4-NPs per kg of soil), the damage score almost doubled.
Although the indirect damage of DNA by ROS production is the main mechanism of the
NPs genotoxicity, our study showed no significant alterations on the tested antioxidant
enzymes and the content of TBARS, suggesting that the damage on the genetic material
might not related to oxidative stress, going against the conclusions of Salvaterra et al.[15],
at least for invertebrate species. The absence of alterations in these oxidative stress
biomarkers seems to indicate that the TiSiO4-NPs interact directly or indirectly with the
DNA causing the observed genotoxicity.
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59
In our study we used NPs with a size smaller than 50 nm. However we have to take
in consideration that all the previous studies done with TiSiO4-NPs, authors noted a high
tendency to the formation of TiSiO4-NPs aggregations bigger than 100 nm in aqueous
suspensions[14]. Although we contaminated the soil directly with the NPs, deionized water
was added immediately, leading most likely to the formation of aggregations. These
aggregations may cause a reduction in the NPs potential to exert their toxicity since 100nm
seems to be the limit for many of the NPs to exert their negative influences[33]. Although
size seems to matter when talking about the toxicity, the chemical and other physical
properties of the NPs also play an important role[33]. The size of aggregates was suggested
by Lopes et al.[14] as one of the possible reasons for the lack of genotoxicity of the
TiSiO4-NPs in the Ames assay. The same test with different conditions, e.g. the exposure
medium, has led to different results, suggesting that the medium were the NPs are inserted
is important for their genotoxicity (e.g. alterations the in the size of aggregates)[13].
To be able to effectively damage the DNA the NPs need to be internalized first. It is
thought that some NPs can enter the cell by endocytosis, smaller particles can enter the cell
through passive diffusion and larger ones can cause deformations in the membrane and
enter the cell[34]. Two studies performed by Novak. et al.[35], [36], using the invertebrate
Porcellio scaber, reported that feeding the test species with food containing more than
1000 µg of TiO2-NPs per gram, leads to the destabilization of the digestive gland
epithelium cells membrane. At the highest tested concentration, the NPs were internalized.
The authors suggest that the membranes need to be first destabilized for the internalization
of the NPs to occur[35], [36]. The study done by Valent et al.[37], using the same test
species and similar experimental conditions, found that the observed destabilization
resulted mainly by the direct interaction of the NPs with the cell membrane and not
exclusively by the action of oxidative stress.
When inside the cell, smaller NPs (
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60
no genotoxicity was found[38]. Once inside the nucleus, the NPs could interfere with the
cell cycle by chemical binding or by mechanical interaction with the genetic material,
leading to different kinds of damage: strand break, loss of chromosomes and interference
with the DNA replication and transcription[19]. We also have to take in consideration that
the NPs can cause indirect genotoxicity by interacting with proteins inside the nucleus
involved in the normal functioning of the cell cycle[19]. Some NPs can even be genotoxic
without entering the nucleus as the study done by Di Virgilio et al.[39] using Chinese
hamster ovary cells has shown. Aggregates of TiO2-NPs formed vesicles that did not enter
the nucleus but interacted with it and modified its shape causing damage to the genetic
material[39]. In Figure 14 we have an illustration of the cellular uptake of NPs and the
possible routes that these particles use to exert their genotoxicity.
In our study, we used coelomocytes in the genotoxicity tests. These cells are
extremely important for the immunity system of earthworms being involved in a diverse
range of functions like encapsulation, inflammation and phagocytosis[40], and thus,
performing the macrophages functions[41]. The uptake of NPs by the cells differ
accordingly to their type, being the macrophages one of the cell types with larger uptake
(related with their phagocytosis capacity)[42]. The genotoxicity observed using the comet
assay in our work might be related to this bigger capacity to take more NPs in the cell.
Once inside the cell, the NPs could cause the observed damage in the genetic material.
Cells with lower uptake capacity could possibly be immune to the genotoxic effects of our
tested NPs.
In our work we only used a maximum concentration of 1000 mg of NPs per kg of
soil. The other two works available that make use of soil and these NPs used a much higher
concentration. None of them reported toxicity. Genotoxicity was found in Pereira et .al[13]
study using a concentration of 5000 mg per kg of soil and after a exposure time of 30 days.
Our results show that TiSiO4-NPs can be genotoxic at even lower concentrations.
Our work shows that independently of the way that the DNA is damaged by the
TiSiO4-NPs, these particles can be genotoxic and they should be dealt with care. Testing
different types of cells would also be interesting to see if genotoxicity is also observable in
other kind of tissues. Although we did not use mortality has a toxicity indicator, like the
standard toxicity tests, it is interesting to see that no mortality was found. Regular tests that
do not make use of genotoxic biomarkers would not found the potential harmful effects of
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61
these NPs. In the future, it would be interesting to find how these TiSiO4-NPs damage the
genetic material, what are the concentrations present on the environment, and if they are
relevant and potentially genotoxic.
Figure 14: Cellular uptake of nanoparticles and possible routes of genotoxicity[19].
5. Conclusions
Not much information is available about the toxicity of TiSiO4-NPs. This work has shown
that soils contaminated with concentration equal or higher than 444 mg of TiSiO4-NPs per
kg of soil can lead to alteration in the DNA increasing its damage. For the tested oxidative
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stress biomarkers and the conditions used in our work, the DNA damage found might not
be related with this stress condition as no alterations were found in antioxidant enzymes or
products of lipid peroxidation. This could suggest that the genetic material damage might
not be caused by ROS but instead by the direct interaction of the NPs with the DNA or by
any other mechanism of genotoxicity.
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